DE102017129101A1 - Robot arrangement with a buoyant body - Google Patents

Abstract

The present invention relates to a robot arrangement which serves for handling and / or manipulating one or more objects which are located at a greater height above the ground and otherwise can only be achieved with great difficulty by means of a construction connected to the ground. The robot assembly comprises at least one buoyant body (81) for filling with a gas lighter than air and a means (73, 74) for generating an opposing force influencing the equilibrium state of the buoyant body (81). The robot assembly further comprises a platform (76) attached to the buoyancy body (81) which carries at least two robot arms (71, 72).

Description

The present invention relates to a robot assembly having a buoyant body which is intended to be filled with a gas lighter than air.

According to the state of the art, when carrying out installation, repair, cleaning or inspection tasks on structures or other objects at high altitudes, skilled workers are brought to the place of use with technical aids. These technical aids are, in particular, lifting platforms, crane systems, scaffolding and cable systems. However, there are locations where these technical aids can not be used for a variety of reasons, such as limited access areas or floor loads.

The drone technology of the prior art is only suitable for simple visual inspections, which is not sufficient for a building inspection. A disadvantage of the drone technology is the negative environmental impact through the propeller- or nozzle-based thrust generation.

Platforms with buoyant bodies which are lighter than air are known in the prior art. A disadvantage of these platforms is that with the large mass caused by the people and the necessary tools also a large volume of buoyancy body is connected. Accordingly, a large volume of the lift gas is required, whereby high costs arise. The size of the float limits the scope. Another disadvantage is that special demands must be placed on the personnel deployed; u. a. in terms of altitude, health, fitness, qualification and body weight. Often the activities in height can only be realized in certain time windows. Due to the high psychological and physical stress, the deployment time on site is limited.

The product "Robot Balloon" of the manufacturer Aerobotics consists of a balloon, which is lighter than air and on which a radio-controlled camera is mounted. This product is intended to enable surveying work or documentary recordings. The camera is held by a lightweight robot arm, which can also be equipped with tools. In practical use, however, it has been shown that numerous tasks can not be solved with only one robotic arm. In addition, the stability of the prior art product is not sufficient.

The DE 10 2008 002 924 A1 and the EP 2 141 114 A1 show a device for working at high altitudes. The device comprises a work positioning carried by a buoyant body filled with a gas lighter than air. The buoyancy body carries at least one working position that can be used for a manpower and / or technical equipment, which can also be used in the area above the center of gravity on the surface of the buoyant body. The buoyancy body is freely positionable in the space in the x-, y- and z-axis and controllable in its inclination by the application of a means for generating a counterforce affecting the state of equilibrium and can be fixed in a stable position.

The object of the present invention, starting from the prior art, is to facilitate the execution of installation, repair, cleaning or inspection tasks on structures or other objects at high altitudes.

The stated object is achieved by a robot arrangement according to the appended claim 1.

The robot arrangement according to the invention is used for handling and / or manipulating one or more objects which are located at a greater height above the ground and otherwise can only be achieved with great difficulty by means of a construction connected to the ground. The robot assembly includes at least one buoyant body for filling with a gas that is lighter than air. Thus, the robot assembly is designed as a free or tied airship, which can float in the air above the ground. The robot arrangement furthermore comprises a means for generating a counterforce influencing the equilibrium state of the buoyant body. By this means, the buoyant body can be moved to a certain position and / or remain in this position. The robot assembly further comprises a platform attached to the buoyant body which carries at least two robot arms. An object may be manipulated and / or manipulated using the robotic arms, wherein one or more of the robotic arms may be used to fix the position of the buoyant body with the platform and robotic arms thereon such that one or more of the robotic arms provide the means for generating a buoyancy can form the opposing force influencing the equilibrium state of the buoyant body. In principle, however, the robot arrangement comprises at least two of the robot arms, which are designed to handle and / or manipulate one or more objects, in addition to the means for generating a counterforce influencing the equilibrium state of the buoyant body.

A particular advantage of the robot arrangement according to the invention is that the buoyant body does not have to lift a person, so that it can be made correspondingly small, and that the two robot arms can replace humans for many tasks. Since the robot assembly according to the invention can be operated unmanned, it has the advantage that significantly lower safety and protection costs than when using people are required. In addition, longer working cycles and shift of working hours are possible. It is possible to automate and objectify sub-processes through sensory controls, ensuring consistently high quality and documentability. Since the buoyant body can be made small, results in a wide range of uses of the robot assembly.

In preferred embodiments of the robot arrangement according to the invention, the buoyant body is formed by a balloon. The buoyant body may be formed by an impact airship, by a semi-rigid airship or by a rigid airship. In one embodiment as a semi-rigid airship or as a rigid airship, the buoyant body preferably comprises a frame, which primarily serves to stabilize the equilibrium of a shell of the buoyant body.

The gas, which is lighter than air, is preferably formed by helium, although another gas can be used more easily than air or heated air. The buoyant body is preferably filled with the gas, which is lighter than air. The buoyant body is preferably lighter than air. Preferably, the buoyant body including the attached platform with the at least two robot arms is lighter than air.

The platform is preferably attached to an outer wall of the buoyant body. The platform is preferably attached to an upper half of the buoyant body on the outer wall of the buoyant body; in particular above an equator of the buoyant body formed by a balloon. The platform preferably comprises a horizontal plate and a vertical plate fixedly connected thereto, which are integrally formed on the buoyant body. The platform preferably carries the robot arms via a robot arm carrier that can be adjusted in its orientation.

In preferred embodiments of the robot arrangement according to the invention, the means for generating a counterforce influencing the equilibrium state of the buoyant body comprises further robotic arms, traction ropes and / or thrust-generating thrusters which are fastened to the buoyant body. The robot arrangement preferably comprises at least three of the robot arms, wherein two of the robot arms serve for manipulation and / or handling, while the at least one further robot arm forms the means for generating a counterforce influencing the equilibrium state of the buoyant body. Preferably, the robot arrangement comprises four of the robot arms, wherein two of the robot arms serve for manipulation and / or handling, while the two further robot arms form the means for generating a counterforce influencing the equilibrium state of the buoyant body. The alternative or supplementary existing traction cables are each attached at one end to the buoyancy body, while the traction cables are each attached to the other end preferably on a holding device located at the bottom. The holding device preferably comprises a winch for winding the traction cable and / or weights. The holding device is preferably movable on the ground. The alternatively or additionally existing thrust-generating engines are preferably formed by propellers or by impellers. The robot assembly preferably comprises a plurality of the thrust-generating engines, which are aligned in different directions, so that the buoyant body can be driven in different directions. The means for generating a counterforce influencing the equilibrium state of the buoyant body also preferably comprises a weight which is fastened to an underside of the buoyant body, in particular under a center of gravity of the buoyant body. The weight ensures an upright position of the buoyant body with the robot arms located thereon.

In preferred embodiments of the robot arrangement according to the invention, a magazine for tools, grippers, instruments, probes and / or sensors is furthermore arranged on the platform. The tools, grippers, instruments, probes or sensors are accessible through the robot arms. Thus, the robot assembly can be configured for the positioning of the buoyant body for different tasks. The magazine preferably has a plurality of container areas for the tools, grippers, instruments, probes or sensors.

The magazine preferably further comprises container areas for objects and / or samples, which are received during use of the robot assembly in height from the robot assembly and can be transported by a storage in the magazine to the ground. The objects or samples can be picked up by the robot arms and stored by them in the container areas.

The magazine preferably further comprises mechanical interlocks for closing the individual container areas. This can ensure that the contents of the magazine can not fall out of the magazine during the movements of the buoyant body. The latches are preferably electrically actuated.

The magazine preferably further comprises sensors for measuring conditions of the magazine. The states of the magazine are, in particular, fillings of the container areas and closing states of the interlocks of the container areas. Thus it can be detected whether the container areas of the magazine are empty or filled or whether they are open or closed.

The magazine preferably comprises a magazine signal processing unit, which is preferably electrically connected to the sensors of the magazine and / or with the electrically actuated locks. The magazine signal processing unit receives the signals from the sensors. The magazine signal processing unit controls the electrically actuable latches.

The robot assembly preferably further comprises at least one central camera, which is preferably attached directly or indirectly to the platform. In special embodiments, detail cameras can additionally be arranged, for example on the wrist roots of the robot arms. The camera is used for the visual detection of the objects to be inspected, manipulated or handled, and possibly also the robot arms. The camera preferably includes a microphone, so that sound can be recorded. The cameras are preferably equipped with lighting units, in particular LED headlights.

Preferred embodiments of the robot arrangement according to the invention further comprise a control unit remote from the buoyancy body and a control electronics arranged on the buoyancy body. The operating unit and the control electronics are connected to each other via an electrical cable and / or via a wireless connection, so that information can be transmitted from the operating unit to the control electronics and back. The control unit is intended to be used on the ground. An operator can use the operating unit to operate the robot assembly; For example, control the robot arms or view images of the camera.

The control electronics on the buoyancy body is preferably electrically connected to the robot arms and possibly also to the camera and optionally to the sensors used by the robot arms and optionally to sensors located on the platform and / or on the buoyancy body. The sensors preferably include temperature, humidity, pressure, inertial and / or distance sensors. The electrical connection can be wired or wireless. Due to the electrical connection, data can be transmitted from the operating unit via the control electronics to the robot arms or to the sensors and back.

The control electronics are preferably also electrically connected to the magazine signal processing unit. By means of this electrical connection, data can be transmitted from the operating unit via the control electronics and further via the magazine signal processing unit to the sensors on the magazine and / or the electrically actuatable interlocks and back.

The control electronics is preferably mounted on the platform.

The operating unit preferably comprises at least one haptic input device for operating the buoyant body and / or the robot arms. The at least one haptic input device is preferably formed by a joystick, which is preferably designed for control in six dimensions. The operating unit preferably comprises at least two of these joysticks.

The haptic input device is preferably formed by a manually controllable input kinematic, which simulates the robot arms, d. H. that the manually controllable kinematics in their dimension and in their structure corresponds to the kinematics of the robot arms. The haptic input kinematic has joints in which absolute displacement and / or angle measuring systems are located, which in a simple case can be formed by potentiometers. The measured values of these displacement and angle measuring systems form the presetting for the positioning of the respectively associated joints of the robot arms whose actually assumed position, for example, is likewise detected by potentiometers. Thus, a technically simple and intuitive motion control of the robot arms is possible because the kinematics on the robot arm follows directly the input kinematics.

The operating unit preferably comprises a display unit for displaying the images recorded with the camera (s) so that the operator can look at these images on the ground, for example to carry out an inspection. The display unit is preferably formed by a screen or by an upside-down visual output device, for example in the form of a video goggle.

The camera is preferably designed for recording stereoscopic or three-dimensional images, while the display unit is preferably for displaying the stereoscopic or is formed three-dimensional images. The display unit is preferably formed by a 3D glasses, by a 3D display or by a curved screen.

The operating unit preferably additionally includes a display for displaying control information and status information. This display is preferably formed by a screen. The operating unit preferably additionally includes a loudspeaker for the acoustic output of control information and / or status information and / or for playback of recordings of the microphone.

In preferred embodiments of the robot arrangement according to the invention, the operating unit and the control electronics are connected to one another via a bus. The robot assembly preferably also includes a computer configured as a master on the bus. The computer is preferably formed by an industrial PC. The computer is preferably configured to convert and / or store signals from the sensors. The computer is preferably configured to generate control signals for the robot arms in accordance with the inputs on the operating unit. The computer is preferably configured for the visualization of process data. The computer preferably comprises a keyboard for input of process parameters and a monitor.

The robot assembly according to the invention preferably further comprises a power supply unit for the electrical supply of the robot arms and optionally the control electronics. The power supply unit is preferably designed for voltage conversion; in particular for the voltage conversion from a mains voltage to a voltage for operating the robot arms. The power supply unit preferably comprises an electric energy storage, which is preferably formed by an accumulator. With the electric energy storage failures of the mains voltage can be bridged. The power supply unit is preferably arranged away from the buoyancy body and connected via an electrical cable to the control electronics on the buoyant body, so that the power supply unit can be arranged on the ground, for example on the operating unit. Alternatively, the power supply unit is preferably arranged on the buoyant body, for which purpose it comprises an electric energy store, which is preferably formed by an accumulator. The power supply unit is preferably attached to the platform. This embodiment allows a tether-free operation of the buoyant body.

The robot assembly according to the invention preferably comprises four of the robot arms, wherein a first pair of robot arms for manipulation and / or handling of objects, while a second pair of robot arms for fixing the platform or the buoyancy body is used and thus at least partially the means for generating a Balance state of the buoyant body influencing counterforce forms. The second pair of robot arms is preferably disposed below the first pair of robot arms.

In a first preferred embodiment of the robot arms, the robot arms each comprise at least a first arm part and a second arm part, which can transmit the force and the moments for manipulation of the object. The first arm part carries the second arm part or vice versa. The first arm part and the second arm part are connected to each other via a hinge, so that the second arm part is pivotable relative to the first arm part about an axis which is perpendicular to an axis extending along the first arm part and / or perpendicular to one along the second arm part aligned extending axis.

The arm parts each comprise a tubular supporting body. The tube shape allows a high mechanical strength with a low mass. The forces and moments to be transmitted by the arm parts can be transmitted via the tubular base body, so that they form parts of a kinematic chain of the respective robot arm, like the joint. The tubular supporting base bodies each form an outer surface or an outer skin of the arm parts. The tubular supporting body are preferably formed by tubes.

In an interior of the tubular supporting body of the first arm part, there is disposed a linear actuator by which a force is generated to pivot the first arm part and the second arm part to each other via the hinge. The linear actuator has a main extension direction, which is preferably arranged parallel to the tubular supporting body of the first arm part. The linear actuator preferably extends at least over half the length of the tubular base body of the first arm part. A first end of the linear actuator is in mechanical engagement with the first arm part. A second end of the linear actuator is in mechanical engagement with the second arm part. The force that can be generated by the linear actuator acts between its first end and its second end. Driving the linear actuator causes the distance between its first end and its second end to change. Driving of the linear actuator thus results in a force acting between the first arm part and the second arm part, by which the first arm part and the second arm part are pivoted to each other via the joint.

An advantage of this first embodiment of the robot arms is that the tubular base body of the arm parts form an outer shell of the arm parts enclosing the linear actuator and at the same time assume a supporting function. Thus, the arm parts have no supporting elements except the tubular basic bodies. The robot arms are slim, lightweight, robust and safe to carry out. The robot arms are each designed according to the exoskeleton principle. The exoskeleton is formed in each case by the tubular basic body of the arm parts.

Preferably, the at least one joint is hollow. The tubular base body of the arm parts and the hollow joint preferably form a cavity extending through the main body of the two arm parts and over the joint. Thus, the exoskeleton is formed by the tubular body of the arm parts and also by the joint.

The at least one hollow joint preferably has a hinge wall which encloses the cavity formed by the hollow joint. In the hinge wall, at least one rotary bearing is preferably formed with an inner ring and with an outer ring. The inner ring and the outer ring are each disc-shaped. The rotary bearing is preferably formed by a sliding bearing or by a rolling bearing. The inner ring is firmly connected to one of the two arm parts, while the outer ring is firmly connected to the other of the two arm parts. Preferably, two of the rotary bearings are formed in the hinge wall. The two rotary bearings preferably have a same axis of rotation and are arranged axially spaced on the axis of rotation. The axial distance is preferably equal to an outer diameter of the tubular supporting body of the arm parts.

The hinge wall preferably further comprises a flexible sleeve which encloses the cavity formed by the hollow joint up to the tubular base body of the arm parts and up to the at least one rotary bearing.

Preferably, the cavity extending through the base body of the respective two arm parts and over the respective joint is sealed in a dust-tight manner. The cavity extending through the base bodies of the respective two arm parts and over the respective joint is preferably watertight or at least splash-tightly sealed. Preferably, the cavity extending through the base body of the respective two arm parts and over the respective joint is hermetically sealed. The cavity extending through the base bodies of the respective two arm parts and over the respective joint is preferably filled with a protective gas.

The first end of the respective linear actuator is preferably mounted in a pivot bearing relative to the respective first arm part, so that the respective linear actuator can follow the deflection caused by the driving during the driving. The respective pivot bearing is preferably attached to an inner wall of the tubular base body of the respective first arm part.

The second end of the respective linear actuator is preferably mounted on a lever fastened to the respective second arm part. The respective lever preferably extends into the cavity of the respective hollow joint. The second end of the respective linear actuator is preferably mounted within the cavity of the respective hollow joint on the lever.

The respective linear actuator is preferably hydraulically, pneumatically or electrically driven. The respective linear actuator is preferably formed by an electric motor-spindle combination. The respective linear actuator is preferably electrically controllable.

Preferably, the respective second arm part can be pivoted relative to the respective first arm part via the respective joint, even if the respective linear actuator is in a non-driving state. For this purpose, a minimum torque between the respective second arm part and the respective first arm part is applied manually.

The robot arms further preferably each include a robot arm control electronics for controlling the respective linear actuator, in which the main body of the both arm parts and over the hinge extending cavity is arranged. The respective robot arm control electronics are preferably designed to cause defined movements of the respective arm parts. In particular, robotic arm control electronics are located in the respective robot arm for controlling the respective actuators, for detecting the sensor data and for communicating with a master control unit (eg a micro PC), preferably via a bus system. The master control unit may be arranged externally or integrated with the respective robot arm.

The robot arms preferably furthermore each include a sensor system for measuring the pivoting of the respective second arm part relative to the respective first arm part, which is arranged in the cavity extending through the main body of the two arm parts and over the joint. The respective sensor is preferably electrically connected to the respective robot arm control electronics. Electrical connections are also preferably arranged in the cavity extending through the base bodies of the two arm parts and over the hinge.

In a second preferred embodiment of the robot arms, the robotic arms each comprise a rotatable foot, a shoulder arm part carried by the foot, a forearm part carried by the shoulder arm part, a forearm part carried by the upper arm part, a carpal arm part carried by the forearm part, and preferably a gripper carried by the carpal arm part can transmit the moments for handling or manipulation of the object. The rotatable foot, the shoulder arm part, the upper arm part, the forearm part, the carpal arm part and, if applicable, the gripper each form a kinematic chain of the respective robot arm.

The shoulder arm part and the upper arm part are connected to each other in the robot arms via a first joint, so that the respective upper arm part is pivotable relative to the respective Schulterarmteil about an axis which is perpendicular to an axis extending along the Schulterarmteiles axis and / or perpendicular to a along the Upper arm part extending axis is aligned.

The upper arm part and the lower arm part are connected to each other in the robot arms via a second joint, so that the respective forearm part is pivotable relative to the respective upper arm part about an axis which is perpendicular to an axis extending along the upper arm part and / or perpendicular to a along the Forearm part extending axis is aligned.

The forearm part and the carpal arm part are each connected to one another via a third joint in the robot arms so that the respective carpal arm part can be pivoted relative to the respective lower arm part about an axis which is perpendicular to an axis extending along the lower arm part and / or perpendicular to one along the lower arm part Handwurzelarmteiles extending axis is aligned.

In the case of the robot arms, at least the shoulder arm part, the upper arm part and the forearm part each comprise a tubular supporting body. The forces and moments to be transmitted by the respective shoulder arm part, the respective upper arm part and the respective lower arm part are transferable via the tubular basic body so that they form parts of the kinematic chain of the respective robot arm, like the first joint, the second joint and the third joint. The tubular bearing bodies each form an outer surface or an outer skin of the Schulterarmteiles, the upper arm part and the forearm part.

In an interior of the tubular supporting body of the respective Schulterarmteiles a first linear actuator is arranged, through which a force is generated to pivot the respective Schulterarmteil and the respective upper arm part to each other via the respective first joint. A first end of the respective first linear actuator is in mechanical engagement with the respective shoulder arm part. A second end of the respective first linear actuator is in mechanical engagement with the respective upper arm part. The force that can be generated by the first linear actuator acts between its first end and its second end. Driving the first linear actuator causes the distance between its first end and its second end to change. Driving the first linear actuator thus results in a force acting between the shoulder arm part and the upper arm part, by which the shoulder arm part and the upper arm part are pivoted to each other via the first joint. The robot arms preferably each comprise an absolute rotary slide sensor and / or a moment sensor for measuring the pivoting between the respective shoulder arm part and the respective upper arm part.

In an interior of the tubular supporting body of the respective upper arm part, a second linear actuator is arranged, through which a force can be generated in order to pivot the respective upper arm part and the respective lower arm part to each other via the respective second hinge. A first end of the respective second linear actuator stands with the respective upper arm part in one mechanical intervention. A second end of the respective second linear actuator is in mechanical engagement with the forearm part. The force that can be generated by the second linear actuator acts between its first end and its second end. Driving the second linear actuator causes the distance between its first end and its second end to change. Driving the second linear actuator thus results in a force acting between the upper arm part and the lower arm part, by which the upper arm part and the lower arm part are pivoted to each other via the second joint. The robot arms preferably each comprise an absolute rotary slide sensor and / or a moment sensor for measuring the pivoting between the respective upper arm part and the respective lower arm part.

Arranged in an interior of the tubular supporting body of the respective lower arm part is a third linear actuator, by means of which a force can be generated in order to pivot the respective lower arm part and the respective hand root arm part towards each other via the respective third joint. A first end of the respective third linear actuator is in mechanical engagement with the respective lower arm part. A second end of the respective third linear actuator is in mechanical engagement with the respective carpal arm part. The force that can be generated by the respective third linear actuator acts between its first end and its second end. Driving the third linear actuator causes the distance between its first end and its second end to change. Driving the third linear actuator thus results in a force acting between the respective lower arm part and the respective carpal arm part, by means of which the lower arm part and the carpal arm part are pivoted to one another via the third joint. The robot arms preferably each comprise an absolute pivot sensor and / or a moment sensor for measuring the pivoting between the lower arm part and the carpal arm.

The respective Schulterarmteil has a free rotation relative to the respective foot in an axis extending along the Schulterarmteiles axis. This free rotation is each fixed with a first locking element. Thus, the respective Schulterarmteil against the respective foot in the extending along the Schulterarmteiles axis is manually rotatable and manually fixed. Correspondingly, the respective shoulder arm part with the upper arm part carried by the shoulder arm part up to the carried hand root arm part can be manually adjusted by a rotation in this axis and no automatic drive is required for this rotation. The robot arms preferably do not have an automatic drive designed for this rotation. The first respective locking element is preferably designed to fix the described rotation continuously or in stages. The robot arms preferably each have an absolute rotational position sensor for measuring the rotational position of the shoulder arm part relative to the foot in the described axis.

The respective upper arm part has a free rotation relative to the Schulterarmteil in an extending along the upper arm part axis. This free rotation is each fixed with a second locking element. Thus, the respective upper arm part relative to the Schulterarmteil in the longitudinal axis of the upper arm extending axis is manually rotatable and manually fixed. Accordingly, the upper arm part is manually adjustable with the forearm part carried by the upper arm part up to the supported hand root arm part by a rotation in this axis and no automatic drive for this rotation is required. The robot arms preferably do not have an automatic drive designed for this rotation. The respective second locking element is preferably designed to fix the described rotation steplessly or in steps. The robot arms preferably each have an absolute rotational position sensor for measuring the rotational position of the respective upper arm part relative to the respective shoulder arm part in the described axis.

A particular advantage of the second embodiment of the robot arms is that no automatic drive is required for two of the degrees of freedom. The linear actuators, the rotatability of the respective foot and the degrees of freedom of the respective carpal arm part already allow free movement of the respective carpal arm part in the room. Since the robot arms can be carried out very easily due to their tubular supporting body without additional supporting elements, the described rotation of the Schulterarmteiles against the foot and the described rotation of the upper arm part relative to the Schulterarmteil can be performed manually if necessary to the respective robot arm in one for the Execution of the movement task to bring optimal starting position, from which he can perform all desired movements or take positions.

The foot, the first joint, the second joint and / or the third joint are each preferably hollow in the case of the robot arms. Thus, in the case of the robot arms, a cavity preferably extends through the interior of the hollow foot, the tubular base body of the shoulder arm part, the hollow first joint, the tubular base body of the upper arm part, the hollow second joint, the tubular base body of the forearm part and possibly the hollow third one joint. The cavity is preferably dust-tight, waterproof, splash-proof and / or airtight sealed. The cavity is preferably filled with a protective gas.

The robot arms are each designed according to the exoskeleton principle. The exoskeleton is formed by the tubular base body of the respective Schulterarmteiles, the respective upper arm part and the respective lower arm part and possibly also by the respective hollow first joint, the respective hollow second joint and / or the respective hollow third joint.

The rotatability of the rotatable foot is preferably given in the robot arms in each case in a vertical axis. The robot arms preferably each have a first rotary drive for rotating the foot in this axis. The first rotary drive is preferably used to rotate the respective foot relative to a base plate. The foot preferably comprises a rotational position sensor and / or a moment sensor in order to be able to measure the rotation. The respective first rotary drive is preferably formed by an electric motor or by a pneumatic or hydraulic motor. The respective first rotary drive is preferably formed by a combination of an electric motor, a pinion and a toothed ring with internal toothing.

The respective lower arm part is preferably rotatable relative to the respective upper arm part in an axis extending along the lower arm part. The robot arms preferably each have an absolute rotary slide sensor for measuring the rotational position of the respective lower arm part relative to the respective upper arm part in the described axis. The robot arms preferably each have a second rotary drive for rotating the respective lower arm part relative to the respective upper arm part in the axis extending along the lower arm part. The respective second rotary drive is preferably formed by an electric motor or by a pneumatic or hydraulic motor. The respective second rotary drive is preferably formed by a combination of an electric motor, a pinion and a toothed ring with internal teeth. The sprocket is preferably formed on an inner surface of the tubular body of the forearm part or the upper arm part.

In the case of the robot arms, the carpal arm part is preferably rotatable relative to the respective lower arm part in an axis extending along the respective carpal arm part. The robot arms preferably each have a third rotary drive for rotating the respective hand root arm part relative to the respective lower arm part in the axis extending along the hand root arm part. The respective third rotary drive is preferably designed to rotate the respective hand root arm part by more than one revolution relative to the respective lower arm part. The respective third rotary drive is preferably formed by an electric motor or by a pneumatic or hydraulic motor. The respective third rotary drive is preferably formed by a combination of an electric motor, a pinion and a toothed ring with internal teeth. The sprocket is preferably formed on an inner surface of the tubular body of the respective carpal arm or the respective forearm part.

In the case of the robot arms, the gripper is preferably rotatable in each case in an axis extending along the respective gripper with respect to the respective carpal arm part. The robot arms preferably each have a fourth rotary drive for rotating the respective gripper relative to the respective hand root arm part in the axis extending along the gripper. The respective fourth rotary drive is preferably designed to rotate the respective gripper by more than one revolution relative to the respective carpal arm part. The respective fourth rotary drive is preferably formed by an electric motor or by a pneumatic or hydraulic motor. The respective fourth rotary drive is preferably formed by a combination of an electric motor, a pinion and a toothed ring with internal teeth.

In the case of the robot arms, the gripper preferably comprises at least two gripper fingers which can each be moved toward and away from one another with a gripper finger drive, so that objects can be gripped with the respective gripper. The respective gripper preferably comprises a mechanical fixing mechanism for fixing or locking the gripper fingers.

The grippers are preferably each exchangeable to use different adapted gripper can. The robot arms preferably each have a contactless electrical interface to the electrical connection of the respective gripper. The contactless electrical interfaces are each designed to transmit electrical energy and data.

The robot arms preferably each comprise a camera for the optical detection of objects to be handled or manipulated. The respective camera is preferably attached to the respective carpal arm part. The respective camera preferably comprises a microphone for detecting acoustic events in the area of the objects to be handled or manipulated.

The robot arms preferably each comprise a lighting unit for illuminating objects to be handled or manipulated. The respective lighting unit is preferably attached to the carpal arm. The respective lighting unit is preferably formed by an LED headlight.

The robot arms preferably each comprise force sensors on the respective carpal arm. The force sensors are preferably arranged circumferentially around the respective carpal arm part, so that they envelop it axially. The force sensors are used to measure an external force acting on the carpal arm pressure force, so that, for example, haptic functions can be realized. The force sensors are preferably segmented.

The robot arms preferably each comprise an inertial measuring unit, which is preferably arranged in the respective carpal arm part. The inertial measuring unit preferably comprises three acceleration sensors with which the accelerations in the three spatial directions can be measured. The inertial measuring unit preferably comprises three gyrosensors with which the Rotational movements around the three spatial directions can be measured.

The robot arms preferably each comprise a coupling element for coupling the respective other robot arm. The coupling elements are preferably each attached to the respective carpal arm. The coupling elements are preferably formed electromechanically.

The robot arms preferably each comprise a gas and / or fluid connection. The respective gas and / or fluid connection preferably opens into the respective cavity formed by the tubular base body and by the joints. The respective gas and / or fluid connection is preferably designed for the passage of compressed air, protective gas and / or water. In particular, a first supplied with compressed air or fluid line connection for actuation of the respective gripper or a mechanical coupling mechanism (rotatable connection between gripper receptacle and carpal), this first line connection also for the passage of gas (air) or fluid z. B. can be used to clean objects. Via the first line connection, a vacuum can be connected to z. B. to operate a suction pad. Via an optional second conduit connection, which terminates in the respective carpal, an inert gas or air can be used for flushing the interior of the robot arm or for generating an overpressure in the respective robot arm.

The second preferred embodiment of the robot arms preferably also has features that are described in connection with the first preferred embodiment of the robot arms. Correspondingly, the respective first and second arm part of the first preferred embodiment are formed by the respective shoulder and upper arm part or by the respective upper and lower arm part or by the respective lower and carpal arm part of the second preferred embodiment.

The robot arm control electronics are preferably designed to initiate defined movements of the arm parts and to use the sensors to transfer the movement of the respective robot arm in the event of possible collisions into a predefined state of motion. The predefined movement state is preferably formed by a movement stop.

• 1: einen Roboterarm einer bevorzugten Ausführungsform einer erfindungsgemäßen Roboteranordnung in einer Schnittdarstellung;
• 2: eine bevorzugte Ausführungsform der erfindungsgemäßen Roboteranordnung; und
• 3: eine Detailansicht der in 2 gezeigten Roboteranordnung.

Further advantages, details and developments of the invention will become apparent from the following description of preferred embodiments of the invention, with reference to the drawing. Show it:

• 1 a robot arm of a preferred embodiment of a robot assembly according to the invention in a sectional view;
• 2 a preferred embodiment of the robot assembly according to the invention; and
• 3 : a detailed view of in 2 shown robot assembly.

1 shows a robot arm of a preferred embodiment of a robot assembly according to the invention in a sectional view. The robot arm includes a foot 01 which rotates on a base plate 02 is stored. The foot 01 can by using a first rotary actuator 03 opposite the base plate 02 to be rotated about a vertical axis. The first rotary drive 03 includes an electric motor 04 , a pinion 06 and a sprocket 07 ,

The foot 01 wears a shoulder arm part 08 , which essentially by a tubular body 09 is formed. The shoulder arm part 08 carries over a first joint 11 an upper arm part 12 which also essentially by a tubular body 13 is formed. The first joint 11 includes a cuff 14 and two disc-shaped rotary bearings 16 , The cuff 14 and the disc-shaped rotary bearings 16 enclose a cavity, so that the first joint 11 is hollow.

In an interior of the tubular body 09 of the shoulder arm part 08 is a first linear actuator 17 arranged, which serves to the upper arm part 12 opposite the shoulder arm part 08 over the first joint 11 to pivot. A first end 18 of the first linear actuator 17 is in a first pivot bearing 19 stored, which firmly in the tubular body 09 of the shoulder arm part 08 sitting. A second end 20 of the first linear actuator 17 is in a first lever 21 stored, which as an extension of the upper arm 12 fixed to the tubular body 13 of the upper arm part 12 is connected and inside the cuff 14 of the first joint 11 is arranged. The rotary bearings 16 each include an inner ring 22 and an outer ring 23 , respectively according to the tubular body 09 of the shoulder arm part 08 or the tubular body 13 of the upper arm part 12 are firmly connected.

The upper arm part 12 carries over a second joint 24 a forearm part 26 which also essentially by a tubular body 27 is formed. The second joint 24 includes a cuff 28 and two disc-shaped rotary bearings 29 , The cuff 28 and the disc-shaped rotary bearings 29 enclose a cavity, so that the second joint 24 is hollow.

In an interior of the tubular body 13 of the upper arm part 12 is a second linear actuator 31 arranged, which serves the forearm part 26 opposite the upper arm part 12 over the second joint 24 to pivot. A first end 32 of the second linear actuator 31 is in a second pivot bearing 33 stored, which firmly in the tubular body 13 of the upper arm part 12 sitting. A second end 34 of the second linear actuator 31 is in a second lever 36 stored, which as an extension of the forearm part 26 fixed to the tubular body 27 of the forearm part 26 is connected and inside the cuff 28 of the second joint 24 is arranged. The rotary bearings 29 of the second joint 24 each include an inner ring 37 and an outer ring 38 , respectively according to the tubular body 13 of the upper arm part 12 or the tubular body 27 of the forearm part 26 are firmly connected.

In an interior of the tubular body 27 of the forearm part 26 is a second rotary drive 39 arranged, with which the forearm part 26 in a longitudinal direction to the forearm part 26 extending axis relative to the upper arm 12 can be twisted. The second rotary drive 39 includes an electric motor 41 , a pinion 42 and a sprocket 43 ,

The forearm part 26 carries over a third joint 44 a carpal arm part 46 which also essentially by a tubular body 47 is formed. The third joint 44 includes two disc-shaped rotary bearings 48 ,

In an interior of the tubular body 27 of the forearm part 26 is a third linear actuator 49 arranged, which serves to the carpal arm 46 opposite the forearm part 26 over the third joint 44 to pivot. A first end 51 of the third linear actuator 49 is in a third pivot bearing 52 stored, which firmly in the tubular body 27 of the forearm part 26 sitting. A second end 53 of the third linear actuator 49 is with an inner ring 54 the disk-shaped rotary bearing 48 of the third joint 44 connected. The inner ring 54 is fixed to the carpal arm 46 connected. An outer ring 56 the disk-shaped rotary bearing 48 of the third joint 44 is fixed to the forearm part 26 connected.

Between the third joint 44 and the carpal arm part 46 is a third rotary drive 57 arranged, with which the Handwurzelarmteil 46 in a longitudinal direction to the carpal arm 46 extending axis relative to the forearm part 26 can be rotated, this rotation is not limited in terms of a number of revolutions. The third rotary drive 57 includes an electric motor 58 , a pinion 59 and a sprocket 61 ,

The carpal arm part 46 opens into a gripper receptacle 62 ,

2 a preferred embodiment of the robot assembly according to the invention in a perspective view. The robot assembly includes four robot arms 71 . 72 . 73 . 74 that prefers like the one in 1 shown robot arm are executed. The four robot arms 71 . 72 . 73 . 74 are at a platform 76 attached, wherein a first pair of robot arms 71 . 72 via an adjustable robot arm 77 at the platform 76 is attached while a second pair of robot arms 73 . 74 directly on the platform 76 is attached. On the robot arm 77 is still a magazine 78 fastened, which is used for the transport, storage and storage of tools, probes, sensors, samples and other objects (not shown). On the robot arm 77 is still a camera 79 attached, which is an inspection of objects and / or an observation of the actions of the robot arms 71 . 72 . 73 . 74 allows. The platform 76 is on a buoyant body in the form of a balloon 81 attached, which is filled with helium. The balloon 81 is including the platform 76 , the robot arms 71 . 72 . 73 . 74 , the magazine 78 and the camera 79 lighter than air.

The robot arms 71 . 72 . 73 . 74 include as in 1 shown each foot 01 , the shoulder arm part 08 , the upper arm part 12 , the forearm part 26 and the carpal arm part 46 , At the carpal arm parts 46 is in each case via the gripper receptacle 62 (shown in 1 ) a replaceable gripper 82 or a replaceable tool 83 appropriate.

3 shows a detail view of in 2 shown robot assembly. It is in particular the platform 76 and the first pair of robot arms 71 . 72 shown.

LIST OF REFERENCE NUMBERS

01

foot

02

baseplate

03

first rotary drive

04

electric motor

05

-

06

pinion

07

sprocket

08

Schulterarmteil

09

tubular body

10

-

11

first joint

12

upper arm part

13

tubular body

14

cuff

15

-

16

disc-shaped bearing

17

first linear actuator

18

first end

19

first pivot bearing

20

second end

21

first lever

22

inner ring

23

outer ring

24

second joint

25

-

26

forearm part

27

tubular body

28

cuff

29

disc-shaped bearing

30

-

31

second linear actuator

32

first end

33

second pivot bearing

34

second end

35

-

36

second lever

37

inner ring

38

outer ring

39

second rotary drive

40

-

41

electric motor

42

pinion

43

sprocket

44

third joint

45

-

46

Handwurzelarmteil

47

tubular body

48

disc-shaped bearing

49

third linear actuator

50

-

51

first end

52

third pivot bearing

53

second end

54

inner ring

55

-

56

outer ring

57

third rotary drive

58

electric motor

59

pinion

60

-

61

sprocket

62

gripper seating

63

-

64

-

65

-

66

-

67

-

68

-

69

-

70

-

71

robot arm

72

robot arm

73

robot arm

74

robot arm

75

-

76

platform

77

Roboterarmträger

78

magazine

79

camera

80

-

81

balloon

82

grab

83

Tool

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102008002924 A1 [0006]
• EP 2141114 A1 [0006]

Claims (10)

Robot arrangement having at least one buoyant body (81) for filling with a gas lighter than air and with a means (73, 74) for generating a counterforce influencing the equilibrium state of the buoyant body (81), the robot assembly further comprising a platform attached to the buoyancy body (81) (76) which carries at least two robot arms (71, 72). Robot arrangement after Claim 1 , characterized in that the buoyant body is formed by a balloon (81) filled with helium. Robot arrangement after Claim 1 or 2 , characterized in that the means for generating an equilibrium state of the buoyancy body influencing counteracting further robot arms (73, 74), traction cables and / or thrust-generating engines, which are attached to the buoyancy body (81). Robot arrangement according to one of Claims 1 to 3 , characterized in that on the platform (76) further a magazine (78) for tools (83), gripper (82), instruments, probes and / or sensors is arranged, which by the robot arms (71, 72) are tangible. Robot arrangement after Claim 4 , characterized in that the magazine (78) further comprises container areas for objects and / or samples, wherein the objects and / or samples of the robot arms (71, 72) are receivable and can be stored in the container areas. Robot arrangement according to one of Claims 1 to 5 , characterized in that it further comprises a control unit remote from the buoyancy body (81) and a control electronics arranged on the buoyancy body (81), wherein the control unit and the control electronics are connected to each other via a cable or via a wireless connection. Robot arrangement after Claim 6 , characterized in that the operating unit comprises at least one haptic input device for operating the buoyant body (81) and / or the robot arms (71, 72, 73, 74), wherein the haptic input device is formed by at least two joysticks or by a manually controllable input kinematic which simulates the robot arms (71, 72, 73, 74). Robot arrangement after Claim 6 or 7 characterized in that it further comprises a camera (79) mounted on the platform (76), the operating unit comprising a display unit for displaying the images taken with the camera (79). Robot arrangement according to one of Claims 1 to 8th , characterized in that the robot arms (71, 72, 73, 74) each comprise at least one first arm part (08; 12; 26) and a second arm part (12; 26; 46), which are each provided with a hinge (11; 24 44) are connected to each other, wherein the arm parts (08, 12, 26, 46) each comprise a tubular supporting body (09, 13, 27, 47), wherein in an interior of the tubular supporting body (09, 13, 27) A respective linear actuator (17; 31; 49) is arranged, wherein a first end (18; 32; 51) of the respective linear actuator (17; 31; 49) is connected to the respective first arm part (08; 12; 26) are engaged, and wherein a second end (20; 34; 53) of the respective linear actuator (17; 31; 49) is engaged with the respective second arm member (12; 26; 46) respectively stands. Robot arrangement according to one of Claims 1 to 8th characterized in that the robot arms (71, 72, 73, 74) each comprise a rotatable foot (01), a shoulder arm part (08) carried by the foot (01), an upper arm part (12) carried by the shoulder arm part (08), one of Upper arm part (12) supported lower arm part (26) and one of the lower arm part (26) carried Handwurzelarmteil (46), wherein the respective Schulterarmteil (08) and the respective upper arm part (12) via a first joint (11) are interconnected, said respective upper arm part (12) and the respective lower arm part (26) via a second joint (24) are interconnected, wherein the respective lower arm part (26) and the respective Handwurzelarmteil (46) via a third joint (44) are interconnected, wherein at least the respective shoulder arm part (08), the respective upper arm part (12) and the respective lower arm part (26) each comprise a tubular supporting base body (09, 13, 27), wherein in an interior of the tubular supporting basic body a first linear actuator (17) is arranged with a first end (18) of the respective first linear actuator (17) in engagement with the respective shoulder arm part (08), wherein a second end (18) 20) of the respective first linear actuator (17) is in engagement with the respective upper arm part (12), wherein a second linear actuator (31) is arranged in an interior of the tubular supporting base body (13) of the respective upper arm part (12), wherein a first End (32) of the respective second linear actuator (31) is in engagement with the upper arm part (12), wherein a second end (34) of the respective second linear actuator (31) is engaged with the respective lower arm part (26), wherein an inside of the tubular supporting body (27) of the respective lower arm part (26) a third A linear actuator (49) is arranged, wherein a first end (51) of the respective third linear actuator (49) with the respective lower arm part (26) is engaged, wherein a second end (53) of the respective third linear actuator (49) with the respective Handwurzelarmteil (46) is in engagement, wherein the respective Schulterarmteil (08) has a free rotation relative to the respective foot (01) in an along the respective Schulterarmteiles (08) extending axis, said free rotation each fixed with a first locking element is, wherein the respective upper arm part (12) has a free rotation relative to the respective Schulterarmteil (08) in a along the respective upper arm part (12) extending axis, and wherein said free rotation is fixed in each case with a second locking element.

Images